This invention concerns catalysts comprising a molybdenum compound of formula (I): Vq MoAy Oz, (II): NiMox By Oz ', (III): VNiw Mox Cy 'Oz ", (IV): CoNiw Mox Dy Oz '", or (V): VNiw COr Mox Ey Oz "", wherein: A is at least one cation selected from the group consisting of cations of Cr, Sb, Co, Ce and Pb; B is at least one cation selected from the group consisting of cations of Sb, Al and W; C is at least one cation selected from the group consisting of cations of Fe, Zn, Al, Sb, Bi, W, Li, Ba, Nb and Sn; D is at least one cation selected from the group consisting of cations of Ba, Mn, Al, Sb, Sn and W; E is at least one cation selected from the group consisting of cations of Fe, Ca, Mn, Sr, Eu, La, Zr, Ga, Sn and Pb; q, r, w, x, y, y', z, z', z", z'" and z"" are as defined in the disclosure. These catalysts can be used in C4 oxidation processes.
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1. A catalyst, comprising a molybdenum compound of formula I, II, III, IV or V:
Vq MoAy Oz I NiMox By Oz ' II VNiw Mox Cy 'Oz " III CoNiw Mox Dy Oz '" IV VNiw Cor Mox Ey Oz "" V wherein: q is a number from 0.1 to 10; r is a number from 0.1 to 10; w is a number from 0.1 to 10; x is a number from 0.1 to 10; y is a number from 0.1 to 10; y' is a number from 0 to 10, A is at least one cation selected from the group consisting of cations of: Cr, Ce and Pb; B is at least one cation selected from the group consisting of cations of: Al and W, C is at least one cation selected from the group consisting of cations of: Fe, Zn, Al, Sb, Bi, W, Li, Ba, Nb and Sn; D is at least one cation selected from the group consisting of cations of: Ba, Mn, Al, Sb, Sn, and W; E is at least one cation selected from the group consisting of cations of: Fe, Ca, Mn, Sr, Eu, La, Zr, Ga, Sn and Pb; and z, z', z", z'", and z"" are determined using the amounts and oxidation states of all cations present in each formula according to the following equations: z=((q times oxidation state of V)+(1 times oxidation state of Mo)+(y times oxidation state of A)) divided by 2 (oxidation state of oxygen); z'=((1 times oxidation state of Ni)+(x times oxidation state of Mo)+(y times oxidation state of B)) divided by 2 (oxidation state of oxygen); z"=((1 times oxidation state of V)+(w times the oxidation state of Ni)+(x times oxidation state of Mo)+(y' times oxidation state of C)) divided by 2 (oxidation state of oxygen); z'"=((1 times oxidation state of Co)+(w times the oxidation state of Ni)+(x times oxidation state of Mo)+(y' times oxidation state of D)) divided by 2 (oxidation state of oxygen); and z""=((1 times oxidation state of V)+(w times the oxidation state of Ni)+(r times the oxidation state of Co)+(x times oxidation state of Mo)+(y' times oxidation state of E)) divided by 2 (oxidation state of oxygen). |
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This application is a national stage filing under 35 U.S.C. 371 of PCT/US97/16563, filed Sep. 18, 1997 which claims priority benefit from Provisional Application No. 60/026,597, filed Sep. 24, 1996.
This invention relates to compounds comprising molybdenum, oxygen and certain cations, and the use of these compounds as catalysts in C4 oxidation processes, especially butane oxidation processes.
Oxidative organic processes are widely used in industrial operations. One commercially valuable process involves the oxidation of butane to maleic anhydride. Maleic anhydride is used as a raw material for products ranging from agricultural chemicals, paints, paper sizing and food additives to synthetic resins. To fill the high demand for this valuable chemical, a variety of commercial processes have been developed.
One important route to maleic anhydride involves the vapor phase oxidation of n-butane over a vanadium/phosphorus oxide (VPO) catalyst. The reaction step involves oxidation of n-butane with air (oxygen) to form maleic anhydride, carbon oxides, water and smaller amounts of partially oxidized by-products. Typically, the process is carried out in fixed-bed reactors, fluid-bed reactors, or more recently in recirculating solids reactors having two reaction zones in which two separate reactions take place with a catalyst (the solid) circulating between the two reaction zones and taking part in reactions in both zones.
A number of non-VPO catalysts have been reported in the literature. Zazhigalov, V. A. et al., in an article entitled "Oxidation of n-butane on Vanadium Molybdenum-Oxide Catalysts", Inst. Fiz. Khim. im. Pisarzhevskogo, Kiev USSR Neftekhimiya (1977), 17 (2), 268-73 describe the activity of V2 O5 -MoO3 catalysts in butane oxidation as passing through a maximum at 25% MoO3, and that a certain catalytic structure consisting of, V4+, V5+ and Mo6+ ions correspond to their preferred catalyst composition. These results obtained at 500-600° C. indicate low catalyst activity at normal operating temperatures.
Mazzochia, C. R. et al., in "Selective Oxidation of Butane in the Presence of NiO--MoO3 catalysts"; An. Quim. Ser. A 79, no. 1 108-113(1983) disclose nickel molybdate catalysts prepared by coprecipitation that exhibit low hydrocarbon conversions. At 475°C, 19% conversion of n-butane was noted with low selectivities to maleic anhydride.
Umit Ozkan and G. L. Schrader, in "Synthesis, Characterization and catalytic behaviour of cobalt molybdates for 1-butene oxidation to maleic anhydride", Applied Catalysis, 23 (1986) 327-338 disclose the use of cobalt molybdate for the oxidation of 1-butene.
In spite of the progress in catalyst and process development over the years, a need still remains for improved non-VPO catalysts useful in the oxidation of C4 hydrocarbons, particularly n-butane, to maleic anhydride and especially catalysts which are active at lower temperatures and have shorter contact times; and it is to that end that the present invention is directed.
The present invention provides a catalyst. comprising a molybdenum compound of formula I, II, III, IV or V:
Vq MoAy Oz I
NiMox By Oz ' II
VNiw Mox Cy 'Oz " III
CoNiw Mox Dy Oz '" IV
VNiw Cor Mox Ey Oz "" V
wherein:
q is a number from 0.1 to 10;
r is a number from 0.1 to 10;
w is a number from 0.1 to 10;
x is a number from 0.1 to 10;
y is a number from 0.1 to 10;
y is a number from 0 to 10,
A is at least one cation selected from the group consisting of cations of: Cr, Sb, Co, Ce and Pb;
B is at least one cation selected from the group consisting of cations of: Sb, Al and W;
C is at least one cation selected from the group consisting of cations of: Fe, Zn, Al, Sb, Bi, W, Li, Ba, Nb and Sn;
D is at least one cation selected from the group consisting of cations of: Ba, Mn, Al, Sb, Sn, and W;
E is at least one cation selected from the group consisting of cations of: Fe, Ca, Mn, Sr, Eu, La, Zr, Ga, Sn and Pb; and
z, z', z", z'", and z"" are determined using the amounts and oxidation states of all cations present in each formula according to the following equations:
z=((q times oxidation state of V)+(1 times oxidation state of Mo)+(y times oxidation state of A)) divided by 2 (oxidation state of oxygen);
z'=((1 times oxidation state of Ni)+(x times oxidation state of Mo)+(y times oxidation state of B)) divided by 2 (oxidation state of oxygen);
z"=((1 times oxidation state of V)+(w times the oxidation state of Ni)+(x times oxidation state of Mo)+(y' times oxidation state of C)) divided by 2 (oxidation state of oxygen);
z'"=((1 times oxidation state of Co)+(w times the oxidation state of Ni)+(x times oxidation state of Mo)+(y' times oxidation state of D)) divided by 2 (oxidation state of oxygen); and
z""=((1 times oxidation state of V)+(w times the oxidation state of Ni)+(r times the oxidation state of Co)+(x times oxidation state of Mo)+(y times oxidation state of E)) divided by 2 (oxidation state of oxygen).
The present invention also provides a process for the oxidation of a C4 hydrocarbon to maleic anhydride, comprising: contacting the C4 hydrocarbon with a source of oxygen in the presence of a catalytic amount of a molybdenum catalyst comprising a compound of formula I, II, III or V, as defined above, to yield maleic anhydride.
The present invention further provides a process for the oxidation of n-butane to maleic anhydride, comprising contacting n-butane with a source of oxygen in the presence of a catalytic amount of a molybdenum catalyst comprising a compound of formula IV, as defined above, wherein the molybdenum catalyst is in a bulk state, to yield maleic anhydride.
The present invention also provides a process for the oxidation of n-butane to maleic anhydride, comprising: contacting n-butane with a source of oxygen in the presence of a catalytic amount of a catalyst comprising a molybdenum compound of formula VI or VII in a crystalline, active phase
V9 Mo6 O40 VI
V2 MoO8 VII
to yield maleic anhydride.
The present invention also provides a process for the preparation of a molybdenum compound comprising a crystalline oxide of formula I, II, IlI, IV or V, as described above, comprising the steps of: contacting at least one compound having a cation of the molybdenum compound with at least one cation containing compound for each of the other cations of the molybdenum compound in a solution comprising water to form a resultant solution or colloid; freezing the resultant solution or colloid to form a frozen material, freeze drying the frozen material; and heating the dried frozen material to yield the molybdenum compound of formula I, II, III, IV, V, VI or VII.
Multicomponent catalyst systems have been identified herein wherein the presence of molybdenum in combination with other particular cations show a significant beneficial effect on catalyst performances compared with many non-VPO catalysts reported in the literature for n-butane oxidation. These new multicomponent catalysts of the present invention comprise a molybdenum compound of formula I, II, III, IV or V:
Vq MoAy Oz I
NiMox By Oz ' II
VNiw Mox Cy 'Oz " III
CoNiw Mox Dy Oz '" IV
VNiw Cor Mox Ey Oz "" V
wherein: q is a number from 0.1 to 10; r is a number from 0.1 to 10; w is a number from 0.1 to 10; x is a number from 0.1 to 10; y is a number from 0.1 to 10; and y' is a number from 0 to 10.
A is at least one cation selected from the group consisting of cations of: Cr, Sb, Co, Ce and Pb. A is preferably Sb, and a preferred compound of formula I is V1 Mo1 Sb1 Oz. B is at least one cation selected from the group consisting of cations of: Sb, Al and W. B is preferably Sb, and a preferred compound of formula II is Ni1 Mo2.3 Sb1 Oz '. C is at least one cation selected from the group consisting of cations of: Fe, Zn, Al, Sb, Bi, W, Li, Ba, Nb and Sn. C is preferably Bi, or Nb and Sn, and preferred compounds of formula III are V1 Mo2.3 Ni1 Bi1 Oz " and V1 Mo2.3 Ni1 Nb1 Sn1 Oz ". D is at least one cation selected from the group consisting of cations of: Ba, Mn, Mo, Al, Sb, Sn, and W. D is preferably Sn or W, and preferred compounds of formula IV are Co0.5 Ni0.5 Mo3 Sn0.5 Oz '" and Mo3 Co0.5 Ni0.5 W1 Oz '". E is at least one cation selected from the group consisting of cations of: Fe, Ca, Mn, Sr, Eu, La, Zr, Ga, Sn and Pb. E is preferably Fe, Sr, Zr, Ga or Pb, and preferred compounds of formula V are V1 Mo2.3 Ni0.5 Co0.5 Fe1 Oz "", V1 Mo2.3 Co0.5 Ni0.5 Sr1 Oz "". V1 Mo2.3 Co0.5 Ni0.5 Zr1 Oz "", V1 Mo2.3 Co0.5 Ni0.5 Ga1 Oz "" and Vl Mo2.3 Co0.5 Ni0.5 Pbl Oz "".
The ranges for z, z', z", z'", and z"" defining the subscript for oxygen in the formulae I-V, varies widely. The value of z, z', z", z'", and z"" is defined using the range of possible oxidation states of all of the cations found in the molybdenum compound as shown below.
For the molybdenum compounds of formula I, the highest oxidation states of the A cations are: V5+, Mo6+, Cr6+, Sb5+, Co3+, Ce4+ and Pb4+ ; and the lowest oxidation states for the A cations are: V3+, Mo4+, Cr2+, Sb3+, Co2+, Ce3+ and Pb2+. Therefore, for example, when the molybdenum compound of formula I is V10 Mo1 A10 Oz, wherein A is Cr, the maximum value for z. zmax, is: zmax =((10×5)+(1×6)+(10×6))÷by 2=116/2=58. The minimum value for z, zmin, in formula I wherein A is Cr is: zmin =((10×3)+(1×4)+(10×2))÷by 2=54/2=27. When the molybdenum compound of formula I is V0.1 Mo1 A0.1 Oz, wherein A is Pb, zmax =((0.1×5)+(1×6)+(0.1×4))÷by 2=6.9/2=3.45. The minimum value for z, zmin, in formula I wherein A is Pb is: zmin =((0.1×3)+(1×4)+(0.1×2))÷by 2=4.5/2=2.25. Thus, for molybdenum compounds of formula I, z ranges from 2.25 to 58.
For molybdenum compounds of formula II, the highest oxidation states are: Ni3+, Mo6+, Sb5+, Al3+, and W6+ and the lowest oxidation states are: Ni2+, Mo2+, Sb3+, Al3+, and W2+. z'max and z'min can be calculated as shown above for zmax and zmin of formula I.
For molybdenum compounds of formula III, the highest oxidation states are: V5+, Ni3+, Mo6+, Fe3+, Zn2+, Al3+, Sb5+, Bi5+, W6+, Li1+, Ba2+, Nb5+, and Sn4+, and the lowest oxidation states are: V2+, Ni2+, Mo2+, Fe2+, Zn2+, Al3+, Sb3+, Bi3+, W2+, Li1+, Ba2+, Nb3+, and Sn2+. z"max and z"min can be calculated as shown above for zmax and zmin of formula I. Since there can be mixtures of the C cations, these must be factored into the ranges for z.
For molybdenum compounds of formula IV, the highest oxidation states are: Co3+, Ni3+, Mo6+, Ba2+, Mn7+, Al3+, Sb5+, Sn4+, and W6+, and the lowest oxidation states are: Co2+, Ni2+, Mo2+, Ba2+, Mn2+, Al3+, Sb3+, Sn2+, and W2+. z'"max and z'"min can be calculated as shown above for zmax and zmin of formula I.
For molydbenum compounds of formula V, the highest oxidation states are: V5+, Ni3+, Co3+, Mo6+, Fe3+, Ca2+, Mn7+, Sr2+, Eu3+, La3+, Zr4+, Ga3+, Sn4+ and Pb4+, and the lowest oxidation states are: V2+, Ni2+, Co2+, Mo2+, Fe2+, Ca2+, Mn2+, Sr2+, Eu2+, La3+, Zr4+, Ga3+, Sn2+ and Pb2+. z""max and z""min can be calculated as shown above for zmax and zmin of formula I.
The catalysts of the present invention can be either a particular structure (containing a certain ratio of cations) or a combination of structures and thus comprise a mixture of the crystalline oxides of the molybdenum compound of formula I, II, III, IV or V and may further comprise the amorphous phase of the compound.
The molybdenum compounds of the present invention can be prepared by various methods, for example, by freeze drying, alcohol reflux and gel techniques. Spray roasting, spray drying and coprecipitation could also be employed. Ceramic methods, i.e., solid state techniques could be used but are, in general, less preferred. Certain compounds of formulas I-V are better prepared by one method over another as appreciated by one of ordinary skill in the art.
The catalyst preparative process is usually conducted at normal atmospheric pressure, but elevated or reduced pressures can be employed. Agitation is not required, but is usually provided to facilitate a homogeneous mix and to facilitate heat transfer.
One process for the preparation of a catalyst comprising a molybdenum compound of formulas I, II, III, IV, V, VI or VII, as described above, comprises contacting at least one cation containing compound with at least one cation containing compound for each of the other cations of the final molybdenum compound in a solution comprising water to form a resultant solution or colloid; freezing the resultant solution or colloid to form a frozen material; freeze drying the frozen material; and heating the dried frozen material to yield the molybdenum compound of formula I, II, III, IV, V, VI or VII.
The compound containing a cation of the final molybdenum compound of formula I, II, III, IV, V, VI or VII can be a salt, oxide or the like. The cation containing compounds are contacted with each other upon their addition to the solution comprising water. There is at least one cation containing compound for each of the cations in the molybdenum compound of formula I, II, III, IV, V, VI or VII. Each cation can be contained in a separate cation containing compound or more than one cation can be contained in the same cation containing compound. There can also be more than one cation containing compound for each cation in the final molybdenum compound of formulas I, II, III, IV. V, VI or VII. The cation containing compounds can be ammonium or sodium salts of molybdic acid, vanadic acid or tungstic acid, in addition to compounds containing the A, B, C, D, E cation of choice or other cations present in the final molybdenum compound of formulas I, II, III, IV, V, VI or VII. For example, the oxides or acetylacetonates, chlorides or acetates of Li, Cr, Mn, Mo, Fe, Co, Ni, Ce, W, Zn, Sr, Nb, Eu, Ba. Zr, Al, Ca, Sn, Pb, Sb, Bi, La and Ga can be cation containing compounds. Representative examples of such salts or oxides containing cations of the final molybdenum compound of formula I, II, III, IV, V, VI or VII can be found in Tables 1-6 of the present invention. Normal commercially available reagents can be used for the cation containing compounds used in the preparation of the molybdenum compound. The highest purity products attainable need not be employed: however the purity of the reagents must be known in order to calculate the gross amount required. In addition the reagents should not be contaminated with any catalyst poison. The amount of reagent employed should be within plus or minus 5%, preferably within plus or minus 2% of the amount indicated by stoichiometry.
The cation containing compounds are dissolved in an appropriate solvent to form a solution or fine colloid. The formation of a solution, as opposed to a colloid, is generally preferred for most effective mixing.
In cases where NH4 VO3 is the cation containing compound used, NH4 VO3 salt can be dissolved in water prior to adding the other cation containing compounds by heating water or other appropriate solvents. The additional cation containing compounds can then be added to form a resultant solution or a finely mixed colloid. The resultant solution or colloid is rapidly frozen at liquid nitrogen temperatures. Rapid freezing ensures the cation containing compounds will remain intimately mixed and will not segregate to any significant degree. The frozen material can then be transferred to a freeze drier, such as a Virtis Freeze Drier (Baltimore, Maryland) equipped with a Unitop unit. The solution is kept frozen while water vapor is removed by evacuation. In order to prevent melting of the frozen material. the freeze drier can be maintained at a temperature ranging from about 0°C to about -40°C, preferably between -40°C to -20°C with a vacuum of 2-10 millitorr. After at least 24 hours, preferably about 2-4 days, the dried sample can be calcined (heated) in air at a temperature ranging from about 250°C to about 500°C, preferably about 400°C for a time sufficient to decompose the cation containing compounds of formula I, II, III, IV, V, VI or VII to form metal oxide phases. This will require heating for a period of about 0.5 hours to about 24 hours.
Freeze drying methods can produce mixtures of solid cation containing compounds which are nearly as well mixed as their solution counterparts. The method is superior to slower solvent evaporation because homogeneity can be lost during the removal of solvent. In addition. in many cases because the cation containing compounds are well mixed, a lower calcination temperature can be used, and can allow for the synthesis of metal oxides with higher surface areas than typically observed by traditional high temperature ceramic syntheses. Choice of calcination temperature and protocols and atmosphere can also influence the types of phases synthesized.
Another process for the preparation of a catalyst comprising a molybdenum compound of formula I, II, III, IV, V, VI or VII, as described above, comprises the steps of: mixing a solution comprising at least one cation containing compound for each of the cations in the molybdenum compound of formula I, II, III, IV, V, VI, VI or VII and an alcohol to form a suspension; heating the suspension to reflux; and isolating the molybdenum compound of formula I, II, III, IV, V, VI or VII.
At least one cation containing compound for each of the cations in the molybdenum compound of formula I, II, III, IV, V, VI or VII are combined with an alcohol or combination of alcohols, such as ethyl alcohol, ethyl alcohol/benzyl alcohol mixtures, 1-propanol, 1-butanol, isobutyl alcohol, 2-methyl-2 propanol, 1-heptanol, neopentyl alcohol, phenol or the like, to form a suspension. The cation containing compounds can be those as described above for the freeze drying process. Mixing or agitation can be supplied via methods known in the art. The preparation can be carried out in a dry box to prevent any hydration. The resulting suspension is next heated to reflux under an inert atmosphere, such as nitrogen, for a time sufficient to ensure a proper solution. After the solution is formed, the solvent can be removed by freeze drying, rotary-evaporation, or a slow drying process after filtering, decanting or the like. The dried material can then be calcined at a temperature ranging from about 250°C to about 500°C, preferably about 400°C, under air for a time sufficient to form the molybdenum compound of formula I, II, III, IV, V, VI or VII. This can take from about 0.5 hours to about 24 hours.
A further process for the preparation of a catalyst comprising a molybdenum compound of formula I, II, III, IV, V, VI or VII, as described above. comprises the steps of: contacting at least one cation containing compound for each cation of the molybdenum compound of formula I, II, III, IV, V, VI or VII with at least one cation containing compound for each of the other cations in the molybdenum compound of formula I, II, III, IV, V, VI or VII in a solution comprising water to form a resultant solution or colloid; stirring the resultant solution or colloid until gelation occurs; and drying the gel to yield the molybdenum compound of formula I, II, III, IV, V, VI or VII.
The cation containing compounds for this gel process can be those as described above for the freeze drying process. Following contact of the cation containing compounds with each other, the resultant solution or colloid is stirred until gelation occurs. In some cases an adjustment of pH is needed to induce gelation. Acid or base can be added depending on the nature of the other ingredients being used in the preparation of the molybdenum compound. Gelation can occur at room temperature at atmospheric pressure. The resulting gel can be dried and then calcined at a temperature ranging from about 250°C to about 450°C, preferably 400°C, under air for a time sufficient to thoroughly dry.
Compounds of formula I, II, III, and V of the present invention are useful as catalysts in the oxidation of C4 hydrocarbons. The present invention provides a process for the oxidation of C4 hydrocarbons to maleic anhydride, comprising: contacting the C4 hydrocarbon with a source of oxygen in the presence of a catalytic amount of a catalyst comprising a molybdenum compound of formula I, II, III or V as defined above. The C4 hydrocarbon is selected from the group consisting of: n-butane, 1-butene, 2-butene and butadiene, and isomers thereof.
In some instances the catalyst may he useful as a lattice oxygen catalyst in the oxidation of C4 hydrocarbons with the ability to selectively oxidize the C4 hydrocarbon in the absence of gas phase oxygen and thus can be the only source of oxygen.
The catalyst comprising the molybdenum compound of formula I, II, III or V can be used alone, supported on a catalyst support or impregnated in a carrier material. Typical support carrier materials are well known to those skilled in the art as are methods of preparing supported or impregnated catalysts. Typical materials comprise silica, titania, zirconia, alumina, thoria, silicon carbide and carbon. The catalyst comprising the molybdenum compound described herein can be used as isolated, or in cases where size and shape of the catalyst is dictated by the requirements of the equipment employed in the subsequent use of the catalyst, the catalyst can be processed or fabricated into various size and shape particles before use by grounding, pelletizing, briquetting, tabulating, or shaping in other ways as required.
A first group of compounds, listed in Table 1 as Examples 1-5, are of formula I: Vq MoAy Oz, where q varies from 0.1 to 1.0, y varies from 0.1 to 10, A is at least one cation selected from the group consisting of cations of Cr, Sb, Co, Ce and Pb, and z is calculated as above. The performance of these molybdenum compounds as catalysts in the oxidation of n-butane is shown in Table 1.
A second group of compounds, listed in Table 2 as Examples 6-9, are of formula II: NiMox By Oz ', where x varies from 0.1 to 10, y varies from 0.1 to 10, B is at least one cation selected from the group consisting of cations of Sb, Al and W and z' is calculated as above. The performance of these molybdenum compounds as catalysts in the oxidation of n-butane is shown in Table 2.
A third group of compounds, listed in Table 3 as Examples 10-21, are of formula III: VNiw Mox Cy 'Oz ", where w varies from 0.1 to 10, x varies from 0.1 to 10, y' varies from 0 to 10, C is at least one cation selected from the group consisting of cations of Fe, Zn, Al, Sb, Bi, W, Li, Ba, Nb and Sn and z" is calculated as above. The performance of these molybdenum compounds as catalysts in the oxidation of n-butane is shown in Table 3.
Another group of compounds, listed in Table 5 as Examples 27-35, are of formula V: VNiw Cor Mox Ey Oz "", where w varies from 0.1 to 10. r varies from 0.1 to 10, x varies from 0.1 to 10, y varies from 0.1 to 10, E is at least one cation selected from the group consisting of cations of Fe, Ca, Mn, Sr, Eu, La, Zr, Ga, Sn and Pb and z"" is calculated as above. The performance of these molybdenum compounds as catalysts in the oxidation of n-butane is shown in Table 5.
The present invention further provides a process for the oxidation of n-butane to maleic anhydride comprising contacting n-butane with a source of oxygen in the presence of a catalytic amount of a catalyst comprising a molybdenum compound of formula IV, as defined above, in a bulk state. In some instances the catalysts comprising a molybdenum compound of formula IV of the present invention are used as catalysts in the bulk state, i.e., not on a support, but as pure compounds. The catalyst comprising the molybdenum compound of formula IV may be the only source of oxygen. The catalytic oxidation can be carried out in a fixed or fluidized bed reactor.
A group of compounds, listed in Table 4 as Examples 22-26, are of formula IV: CoNiw Mox Dy Oz '", where w varies from 0.1 to 10, x varies from 0.1 to 10, y varies from 0.1 to 10, D is at least one cation selected from the group consisting of cations of Ba, Mn, Al, Sb, Sn and W, and z'" is calculated as above. The performance of these molybdenum compounds as catalysts in the oxidation of n-butane is shown in Table 4.
The present invention also provides a process for the oxidation of n-butane to maleic anhydride, comprising: contacting n-butane with a source of oxygen in the presence of a catalytic amount of a catalyst comprising a molybdenum compound of formula VI or VII in a crystalline, active phase
V9 Mo6 O40 VI
V2 MoO8 VII
to yield maleic anhydride. Prepared as herein described, the molybdenum compound of formula VI or VII is formed with little MoO3 by-product. The performance of this molybdenum compound in a crystalline, active phase as a catalyst in oxidation of n-butane is shown in Example 36 of Table 6.
Comparative Examples 37-41, not of this invention, and the performance of these materials as catalysts in the oxidation of n-butane is listed in Table 7.
Prior to use in the microreactor, the catalysts described herein are typically formed into a convenient catalyst shape by pelletizing the catalyst at about 30,000 psi (2.07×106 kPa) or less, to form small disks and crushing the pellet through sieves. For fixed bed reactor evaluations, typically a -40, +60 mesh is used (U.S. Sieve Series). Optionally, one could blend the resultant powder with 1-3% of a die lubricant and pellet binder, such as graphite or Sterotex®, a hydrogenated cottonseed oil, commercially available from Capital City Products Company, Columbus, Ohio, before tabletting. For fluidized bed reactor use, the preferred size range is 20 to 150 micrometers.
Glass and stainless steel are usually employed as the material of construction for the microreactor. This is not critical as long as materials that contaminate the product with catalyst poisons are not employed.
Although processes of the invention are embodied in the following laboratory scale examples, Applicant notes that the invention can be practiced on an industrial scale by making the necessary engineering and design modifications which are customary in the art.
Catalytic oxidation using a catalyst comprising a molybdenum compound of formula I, II, III, IV, V, VI or VII can be carried out in a fixed or fluidized bed reactor or recirculating solids reactor. These catalysts can be utilized advantageously with regard to conversion and selectivity in the wide variety of conventional techniques and reactor configurations employed to conduct the vapor phase oxidation of C4 hydrocarbons to maleic anhydride. For example, the conversion can be conducted in a fixed-bed reactor, whereby the catalyst particles are maintained in a fixed position and are contacted with C4 hydrocarbon and a source of oxygen, typically molecular oxygen, both in appropriate amounts, optionally in the presence of one or more inert diluent gases, at a temperature varying between 200°C and about 450°C, preferably between about 300°C and about 350°C The greatest advantages of using the catalyst of this invention are realized when the conversion of C4 hydrocarbon to maleic anhydride is carried out in a recirculating solids reactor, such as that described in U.S. Pat. No. 4,668,802. This patent discloses an improved process for the selective vapor phase oxidation of n-butane to maleic anhydride over a vanadium/phosphorus/oxygen (VPO) catalyst, whereby the amount of oxygen in the feed gas to the VPO catalyst is limited to less than the stoichiometric amount required for the total amount of n-butane converted in the process. The reduced catalyst resulting from the oxidation is separated from the gaseous product stream and is reoxidized, optionally in a separate reaction zone, before being contacted with n-butane.
The catalysts of the present invention demonstrate good results in activity, conversion and selectivity. Tables 1-6 below show conversion and selectivity after 1 sec and after 3 sec for various catalysts of the present invention and compare these results with those of other catalysts in the art (Table 7).
The reagents for the following examples are commercially available as follows: NH4 VO3, Cr2 O3, (CH3 CO2)7 Cr3 (OH)2, Ce(SO4)2, Fe(NO3)3 -9H2 O, NbCl5, Co(NO3)2 -6H2 O, (CH3 CO2)2 Mn-4H2 O, V2 O5 and La(NO3)3 -5H2 O from Aldrich, Milwaukee, Wis.; NH4 VO3, MoO3, Ni(OOCCH3)2 -4H2 O, NiCl2 -6H2 O, H2 WO4, LiNO3 (anhydrous), SnCl2, (NH4)10 W12 O41 -5H2 O, Co(NO3)2 -6H2 O, and SnCl2 from Alfa, Ward Hill, Mass.; (NH4)6 Mo7 O24 -4H2 O), Ni(NO3)-6H2 O, Al(NO3)3 -9H2 O, Bi(NO3)3 -5H2 O, Ni(NO3)2 -6H2 O, Co(NO3)2 -6H2 O, Al(NO3)3 -9H2 O, Ca(NO3)2 -4H2 O, and Ni(NO3)2, from Baker, Phillipsburg, N.J.; Pb(NO3)2, NiCl2 -6H2 O, Pb(NO3)2, and H3 PO4 from EM Sciences, Gibbstown, N.J.; (NH4)6 Mo7 O24 -4H2 O) from Mallinchkrodt, Erie, Pa.; NH4 VO3, Sb(OOCCH3)3, Co(OOCCH3)2, Zr(SO4)2 -4H2 O and Ga(NO3)3 from J&M, Ward Hill, Mass.; colloidal (Al2 O3) from Nyacol, Ashland, Mass.; Zn(NO3)2 -6H2 O from Fisher, Fairlane, N.J.; and Ba(NO3)2 and EuCl2 from AESAR, Ward Hill, Mass.
The component salts (indicated in the tables) were added to the indicated amount of water. In cases where NH4 VO3 was used, the salt was dissolved in water prior to adding, the other components by bringing the solvent to a boil. The additional salts were then added to form the solution or finely mixed colloid/slurry. The resultant solutions/colloids were rapidly frozen in glass dishes (3" diameter) using liquid nitrogen. The frozen material was then transferred to a Virtis Freeze Drier (Baltirnore, Md.) equipped with a Unitop unit. In order to prevent melting of the frozen solid, the Unitop chamber shelves were maintained between -40 to -20°C with a vacuum of 2-10 millitorr. After at least 24 hours (usually 2-4 days), the dried sample was calcined (heated) in air to 400°C for 5 hours to produce the final catalyst product. Prior to microreactor evaluations, the material was pelletized at 20,000 psi and crumbled and screened on -40, +60 mesh screens.
Specific Preparation of V2 MoO8
Vanadium pentoxide, V2 O5, 90.94 g 0.500 mol, and molybdic oxide, MoO3, 71.97 g, 0.500 mol were combined in an round bottomed flask equipped with an agitator with 1034 ml of isobutyl alcohol and 95 ml of benzyl. The resulting suspension was heated to reflux under a nitrogen atmosphere for 16 hours. The resulting green suspension was filtered and the isolated product dried and then calcined at 400°C under air for 5 hours.
Specific preparation of NiMo2.3 AlOz '
35 ml of water was added to the colloidal alumina (20% by weight). The solid oxide and nickel acetate was added. The mixture was stirred until gelation occurred. The gel was dried then calcined at 400°C under air for 5 hours.
The catalysts were pelletized at 1.38×106 kPa into disks and subsequently crushed and sieved through (-40, +60) mesh screens. Approximately 0.9 cc of catalyst were used for each evaluation.
The catalyst testing facility consisted of six micro-reactors which were connected to a common feed source and a common analytical gas chromatograph (GC). Each of the micro-reactors consisted of a 5.0 cm by 0.64 cm stainless steel tube which was immersed in an individual sandbath to maintain isothermal conditions. The feed composition and individual reactor flow rates were metered by commercially available mass flow controllers (Tylan Model FC-260, available from Tylan Corp. Torrance. Calif.). All exit gas lines were heated to 200°C and connected to a multiport Valco valve for the on-line analysis of products using a commercially available GC (Hewlitt-Packard 5890 Series II. Hewlitt-Packard, Palo Alto, Calif.). A computer program controlled the Valco valve to select a reactor or feed stream to fill the 0.5 ml sample loop for injection in the GC. The GC was used to analyze for butane, maleic anhydride, acetic acid, acrylic acid, other C1 to C4 hydrocarbons, oxygen, carbon monoxide, carbon dioxide, nitrogen and water.
The standard testing protocol for butane oxidation catalysts was developed to measure maleic anhydride selectivities and yields under hydrocarbon-lean conditions (2% n-butane, 20% oxygen) over a range of butane conversions. Temperature was varied from 350° to 380° to 400° and back to 350°C, with three contact times (nominally 3, 1, and 0.5 s) evaluated at each temperature. The temperature was returned to 350°C to provide information about the equilibration of the catalyst. The conversion and selectivity of two representative evaluations (at 380°C) are reported in the tables below.
TBL TABLE 1 380°C, 2.0% Butane/Air 1 sec 3 sec Composition Gram Mole Method of Conversion Selectivity Conversion Selectivity Vq MoAy Oz Example Salt Used Weight Solvent Synthesis % % % % V1 Mo1 Cr1 Oz 1 NH4 VO3, 50% 116.98 250 ml H2 O freeze-dried 41 6 75 2 V2 O5 50% 181.90 Cr2 O3 151.99 (CH3 CO2)7 Cr3 (OH)2 602.32 (NH4)6 Mo7 O24 -4H2 O 1235.90 MoO3 143.94 V1 Mo1 Sb1 Oz 2 NH4 VO3 116.98 250 ml H2 O freeze-dried 75 7 99 2 (NH4)6 Mo7 O24 -4H2 O 1235.90 Sb(OOCCH3)3 298.88 V1 Mo1 Co1 Oz 3 NH4 VO3 116.98 250 ml H2 O freeze-dried 70 3 99 0 (NH4)6 Mo7 O24 -4H2 O 1235.90 Co(OOCCH3)2 177.023 V1 Mo1 Ce1 Oz 4 NH4 VO3 116.965 250 ml H2 O freeze-dried 18 9 45 4 (NH4)6 Mo7 O24 -4H2 O 1235.9 Ce(SO4)2 332.24 V1 Mo1 Pb1 Oz 5 NH4 VO3 116.965 250 ml H2 O freeze-dried 15 8 33 4 (NH4)6 Mo7 O24 -4H2 O 1235.9 Pb(NO3)2 331.2 TBL TABLE 2 380°C, 2.0% Butane/Air Gram 1 sec 3 sec Composition Mole Method of Conversion Selectivity Conversion Selectivity NiMox By Oz' Example Salt Used Weight Solvent Synthesis % % % % Ni1 Mo2.3 Sb1 Oz' 6 Sb(OOCCH3)3 298.88 59 cc of freeze-dried 10 21 26 12 (NH4)6 Mo7 O24 -4H2 O 1235.9 30% HCl Ni(OOCCH3)2 -4H2 O 248.82 Ni1 Mo2.3 Al1 Oz' 7 Ni(OOCCH3)2 -4H2 O 248.8212 35 ml H2 O gel 21 6 46 <1 (NH4)6 Mo7 O24 -4H2 O 1235.9 colloidal (Al2 O3) 20% by 101.9613 wt. Ni1 Mo1.3 W1 Oz' 8 (NH4)6 Mo7 O24 -4H2 O 1235.86 50 ml H2 O freeze-dried 10 13 24 2 NiCl2 -6H2 O 237.71 70 ml NH4 OH H2 WO4 249.86 Ni1 Mo1 W1.3Oz' 9 (NH4)6 Mo7 O24 -4H2 O 1235.86 40 ml H2 O freeze-dried 10 11 35 0 NiCl2 -6H2 O 237.71 90 ml NH4 OH H2 WO4 249.86 25 ml H2 O TBL TABLE 3 380°C, 2.0% Butane/Air Gram 1 sec 3 sec Composition Exam- Mole Method of Conversion Selectivity Conversion Selectivity VNiw Mox Cy' Oz' ple Salt Used Weight Solvent Synthesis % % % % V1 Mo2.3 Ni1 Oz" 10 NH4 VO3 116.98 100 cc H2 O freeze-dried 40 21 71 15 (NH4)6 Mo7 O24 -4H2 O 1235.86 100 cc H2 O NiCl2 -6H2 O 237.71 20 cc HCl V1 Mo2.3 Ni1 Fe1 Oz" 11 NH4 VO3 116.98 100 cc H2 O freeze-dried 28 7 60 <1 (NH4)6 Mo7 O24 -4H2 O 1235.86 100 cc H2 O Ni(NO3)-6H2 O 290.81 20 cc HNO3 Fe(NO3)3 -9H2 O 404 V1 Mo2.3 Ni1 Zn1 Oz" 12 NH4 VO3 116.98 100 cc H2 O freeze-dried 53 6 83 <1 (NH4)6 Mo7 O24 -4H2 O 1235.86 100 cc H2 O Ni(NO3)-6H2 O 290.81 20 cc HNO3 Zn(NO3)2 -6H2 O 297.47 V1 Mo2.3 Ni1 Al1 Oz" 13 NH4 VO3 116.98 100 cc H2 O freeze-dried 45 5 79 0 (NH4)6 Mo7 O24 -4H2 O 1235.86 100 cc H2 O Ni(NO3)-6H2 O 290.81 20 cc HNO3 Al(NO3)3 -9H2 O 375.13 V1 Mo2.3 Ni1 Sb1 Oz" 14 NH4 VO3 116.98 100 cc H2 O freeze-dried 39 10 69 5 (NH4)6 Mo7 O24 -4H2 O 1235.86 100 cc H2 O Ni(NO3)-6H2 O 290.81 15 cc HNO3 Sb(OOCCH3)3 298.88 50 cc HCl V1 Mo2.3 Ni1 Bi1 Oz" 15 NH4 VO3 116.98 100 cc H2 O freeze-dried 20 15 50 7 (NH4)6 Mo7 O24 -4H2 O 1235.86 100 cc H2 O Ni(NO3)-6H2 O 290.81 20 cc HNO3 Bi(NO3)3 -5H2 O 485.07 30 cc HNO3 V1 Mo2.3 Ni1 W1 Oz" 16 NH4 VO3 116.98 100 cc H2 O freeze-dried 30 10 71 2 (NH4)6 Mo7 O24 -4H2 O 1235.86 100 cc H2 O Ni(NO3)-6H2 O 290.81 20 cc HNO3 H2 WO4 249.86 V1 Mo2.3 Ni1 Li1 Oz" 17 NH4 VO3 116.98 100 ml H2 O freeze-dried 11 17 20 11 (NH4)6 Mo7 O24 -4H2 O 1235.86 NiCl2 -6H2 O 237.71 15 ml HCl LiNO3 (anhydrous) 68.9459 V1 Mo2.3 Ni1 Ba1 Oz" 18 NH4 VO3 116.98 100 ml H2 O freeze-dried 35 10 66 2 (NH4)6 Mo7 O24 -4H2 O 1235.86 100 ml H2 O Ni(NO3)-6H2 O 290.81 20 ml HNO3 Ba(NO3)2 261.3398 V1 Mo2.3 Ni1 Nb1 Fe1 Oz" 19 NH4 VO3 116.98 100 cc H2 O freeze-dried 30 3 60 <1 (NH4)6 Mo7 O24 -4H2 O 1235.86 50 cc H2 O NiCl2 -6H2 O 237.71 20 cc HCl NbCl5 270.71 70 cc HCl Fe(NO3)3 -9H2 O 404 V1 Mo2.3 Ni1 Nb1 Sn1 Oz" 20 NH4 VO3 116.98 100 ml H2 O freeze-dried 40 12 68 3 (NH4)6 Mo7 O24 -4H2 O 1235.86 70 ml H2 O NiCl2 -6H2 O 237.71 20 ml HCl NbCl5 270.17 20 ml HCl SnCl2 189.61 50 ml H2 O V1 Mo2.3 Ni1 W1 Sn1 Oz" 21 (NH4)10 W12 O41- 3132.64 140 ml freeze-dried 25 10 47 3 5H2 O 1235.86 NH4 OH (NH4)5 Mo7 O24 -4H2 O 116.98 NH4 VO3 290.81 50 ml H2 O Ni(NO3)2 -5H2 O 189.61 SnCl2 5 ml HCl TBL TABLE 4 380°C, 2.0% Butane/Air 1 sec 3 sec Composition Gram Mole Method of Conversion Selectivity Conversion Selectivity CoNiw Mox Dy Oz" Example Salt Used Weight Solvent Synthesis % % % % Co0.5 Ni0.5 Mo3 22 Co(NO3)2 -6H2 O 291.03 20 ml H2 O freeze-dried 12.5 32 29 27 Sn0.5Oz''' SnCl2 189.61 (NH4)6 Mo7 O24 -4H2 O 1235.86 50 ml H2 O NiCl2 -6H2 O 237.71 20 ml HNO3 Mo3 Co0.5 Ni0.5 23 Co(NO3)2 -H2 O 291.03 20 ml H2 O freeze-dried 1.3 4 2.3 11 Mn1 Oz''' (CH3 CO2)2 Mn-4H2 O 245.09 (NH4)6 Mo7 O24 -4H2 O 1235.86 30 ml H2 O NiCl2 -6H2 O 237.71 20 ml H2 O Mo3 Co0.5 Ni0.5 24 Co(NO3)2 -6H2 O 291.03 20 ml H2 O freeze-dried 0.8 16 2.1 18 Ba1 Oz''' Ba(NO3)2 261.34 (NH4)6 Mo7 O24 -4H2 O 1235.86 80 ml H2 O NiCl2 -6H2 O 237.71 20 ml H2 O Mo3 Co0.5 Ni0.5 25 Co(NO3)2 -6H2 O 291.03 20 ml H2 O freeze-dried 3.9 15 10.5 8 Al1 Oz''' Al(NO3)3 -9H2 O 375.13 (NH4)6 Mo7 O24 -4H2 O 1235.86 150 ml H2 O NiCl2 -6H2 O 237.71 20 ml H2 O Mo3 Co0.5 Ni0.5 26 Co(NO3)2 -6H2 O 291.03 40 ml H2 O freeze-dried 4.2 27 14.2 15 W1 Oz''' (NH4)10 W12 O41 -5H2 O 3132.64 (NH4)6 Mo7 O24 -4H2 O 1235.86 50 ml H2 O NiCl2 -6H2 O 237.71 10 ml H2 O TBL TABLE 5 380°C, 2.0% Butane/Air Gram 1 sec 3 sec Composition Exam- Mole Method of Conversion Selectivity Conversion Selectivity VNiw Cor Mox Ey Oz''' ple Salt Used Weight Solvent Synthesis % % % % V1 Mo2.3 Ni0.5 Co0.5 27 NH4 VO3 116.98 50 ml H2 O freeze-dried 15 13 32 7 Fe1 Oz'''' (NH4)6 Mo7 O24 -4H2 O 1235.86 20 ml H2 O Co(OOCCH3)2 177.02 20 ml HCl Ni(NO3)2 -6H2 O 290.81 Fe(NO3)3 -9H2 O 404 20 ml H2 O V1 Mo2.3 Ni0.5 Co0.5 28 NH4 VO3 116.98 50 ml H2 O freeze-dried 14 10 34 4 Ca1 Oz'''' (NH4)6 Mo7 O24 -4H2 O 1235.86 Co(OOCCH3)2 177.02 20 ml HCl Ni(NO3)2 -6H2 O 290.81 5 ml HCl Ca(NO3)2 -4H2 O 236.15 V1 Mo2.3 Co0.5 Ni0.5 29 NH4 VO3 116.98 50 ml H2 O freeze-dried 12.5 2.5 29.2 1 Mn1 Oz'''' (NH4)6 Mo7 O24 -4H2 O 1235.86 20 ml H2 O Co(OOCCH3)2 177.02 20 ml HCl Ni(NO3)2 -6H2 O 290.81 (CH3 CO2)2 Mn-4H2 O 245.09 10 ml H2 O V1 Mo2.3 Co0.5 Ni0.5 30 NH4 VO3 116.98 50 ml H2 O freeze-dried 21 17 47 10 Sr1 Oz'''' (NH4)6 Mo7 O24 -4H2 O 1235.86 20 ml HCl Co(OOCCH3)2 177.02 10 ml H2 O Ni(NO3)2 -6H2 O 290.81 Sr(NO3)2 211.63 V1 Mo2.3 Co0.5 Ni0.5 31 NH4 VO3 116.98 50 ml H2 O freeze-dried 24 7.5 54 2 Eu1 Oz'''' (NH4)6 Mo7 O24 -4H2 O 1235.86 Co(OOCCH3)2 177.02 20 ml HCl Ni(NO3)2 -6H2 O 2908.1 EuCl2 222.87 10 ml H2 O V1 Mo2.3 Co0.5 Ni0.5 32 NH4 VO3 116.98 50 ml H2 O freeze-dried 17 10 36 5 La1 Oz'''' (NH4)6 Mo7 O24 -4H2 O 1235.86 Co(OOCCH3)2 177.02 20 ml HCl Ni(NO3)2 -6H2 O 290.81 La(NO3)3 -5H2 O 415.01 10 ml H2 O V1 Mo2.3 Co0.5 Ni0.5 33 NH4 VO3 116.98 50 ml H2 O freeze-dried 20 17.5 46 12 Zr1 Oz'''' (NH4)6 Mo7 O24 -4H2 O 1235.86 Co(OOCCH3)2 177.02 20 ml HCl Ni(NO3)2 -6H2 O 290.81 Zr(SO4)2 -4H2 O 355.32 40 ml H2 O V1 Mo2.3 Co0.5 Ni0.5 34 NH4 VO3 116.98 50 ml H2 O freeze-dried 18 16.5 43 11 Ga1 Oz'''' (NH4)6 Mo7 O24 -4H2 O 1235.86 Co(OOCCH3)2 177.02 20 ml HCl Ni(NO3)2 -6H2 O 290.81 Ga(NO3)3 255.74 V1 Mo2.3 Co0.5 Ni0.5 35 NH4 VO3 116.98 50 ml H2 O freeze-dried 22 20 47 14 Pb1 Oz'''' (NH4)6 Mo7 O24 -4H2 O 1235.86 (with dry ice Co(OOCCH3)2 177.02 20 ml HCl and acetone) Ni(NO3)2 -6H2 O 290.81 Pb(NO3)2 331.2 100 ml HCl 86 ml NH4 OH TBL TABLE 6 380°C, 2.0% Butane/Air Gram 1 sec 3 sec Exam- Mole Method of Conversion Selectivity Conversion Selectivity Composition ple Salt Used Weight Solvent Synthesis % % % % V2 Mo1 Ox 36 V2 O5 90.94 g 181.88 1034 ml isobutyl alcohol Alcohol reflux 60 10 90 0 MoO3 71.97 g 143.94 95 ml benzyl alcohol TBL TABLE 7 380°C, 2.0% Butane/Air 1 sec 3 sec Comp. Gram Mole Method of Conversion Selectivity Conversion Selectivity Composition Example Salt Used Weight Solvent Synthesis % % % % MoO3 37 (NH4)6 Mo7 O24 -4H2 O 1235.9 freeze-dried 11 <1 VPO 38 NH4 VO3 116.965 freeze-dried 8 20 H3 PO4 97.97 Ni1 W2.3 Ot 39 H2 WO4 249.86 50 ml H2 O freeze-dried 2.5 0 9 0 NiCl2 -6H2 O 237.71 180 ml NH4 OH Ni1 Mo2.3 P1 Ot 40 Ni(NO3)2 290.8 50 ml H2 O freeze-dried 6 12 (NH4)6 Mo7 O24 -4H2 O 1235.86 100 ml H2 O H3 PO4 98 V2 O5 41 freeze-dried 80 <1Kourtakis, Kostantinos, Sullivan, John Donal
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